Your search keyword '"Minaev, Sergei S."' showing total 5 results

1. The effect of depletion of radicals on freely propagating hydrocarbon flames

Author

Gubernov, Vladimir V., Minaev, Sergei S., Babushok, Valeri I., and Kolobov, Andrey V.

Published

2015

2. Phenomenological model of chain-branching premixed flames.

Author

Gubernov, Vladimir V., Babushok, Valeri I., and Minaev, Sergei S.

Subjects

FOSSIL fuels, FLAME temperature, ADIABATIC temperature, THEORY of wave motion, FLAME, CHEMICAL decomposition

Abstract

In this work, we introduce a global kinetic model that includes fuel, oxygen, products and two radical species involved in the reversible chain-branching, chain-propagation and chain-termination reactions. The model naturally extends the Zeldovich–Liñán and Zeldovich–Barenblatt–Dold models and can be used to describe both premixed and diffusion flames. Here it is applied to the problem of the deflagration wave propagation in the hydrocarbon fuel/air mixture with arbitrary equivalence ratio under the simplifying thermal-diffusive approximation. The conservation equations are solved numerically in order to obtain the velocity and structure of the combustion wave. It is demonstrated that the peak values of the adiabatic flame temperature and deflagration velocity are shifted towards the rich mixture composition if the reverse reactions of product decomposition are taken into account. The dependence of the flame speed and temperature on parameters of the system is analysed. The prospects of further investigation are discussed. [ABSTRACT FROM AUTHOR]

Published

2019

3. Influence of water mist on propagation and suppression of laminar premixed flame.

Author

Belyakov, Nikolay S., Babushok, Valeri I., and Minaev, Sergei S.

Subjects

GAS mixtures, VAPORIZATION, FLAMMABILITY, HEAT losses, HYSTERESIS

Abstract

The combustion of premixed gas mixtures containing micro droplets of water was studied using one-dimensional approximation. The dependencies of the burning velocity and flammability limits on the initial conditions and on the properties of liquid droplets were analyzed. Effects of droplet size and concentration of added liquid were studied. It was demonstrated that the droplets with smaller diameters are more effective in reducing the flame velocity. For droplets vaporizing in the reaction zone, the burning velocity is independent of droplet size, and it depends only on the concentration of added liquid. With further increase of the droplet diameter the droplets are passing through the reaction zone with completion of vaporization in the combustion products. It was demonstrated that for droplets above a certain size there are two stable stationary modes of flame propagation with transition of hysteresis type. The critical conditions of the transition are due to the appearance of the temperature maximum at the flame front and the temperature gradient with heat losses from the reaction zone to the products, as a result of droplet vaporization passing through the reaction zone. The critical conditions are similar to the critical conditions of the classical flammability limits of flame with the thermal mechanism of flame propagation. The maximum decrease in the burning velocity and decrease in the combustion temperature at the critical turning point corresponds to predictions of the classical theories of flammability limits of Zel'dovich and Spalding. The stability analysis of stationary modes of flame propagation in the presence of water mist showed the lack of oscillatory processes in the frames of the assumed model. [ABSTRACT FROM AUTHOR]

Published

2018

4. Simple model of inhibition of chain-branching combustion processes.

Author

Babushok, Valeri I., Gubernov, Vladimir V., Minaev, Sergei S., and Miroshnichenko, Taisia P.

Subjects

INHIBITION (Chemistry), CHAIN scission, HYDROCARBONS, CHEMICAL reactions, CHEMICAL inhibitors, HEAT transfer

Abstract

A simple kinetic model has been suggested to describe the inhibition and extinction of flame propagation in reaction systems with chain-branching reactions typical for hydrocarbon systems. The model is based on the generalised model of the combustion process with chain-branching reaction combined with the one-stage reaction describing the thermal mode of flame propagation with the addition of inhibition reaction steps. Inhibitor addition suppresses the radical overshoot in flame and leads to the change of reaction mode from the chain-branching reaction to a thermal mode of flame propagation. With the increase of inhibitor the transition of chain-branching mode of reaction to the reaction with straight-chains (non-branching chain reaction) is observed. The inhibition part of the model includes a block of three reactions to describe the influence of the inhibitor. The heat losses are incorporated into the model via Newton cooling. The flame extinction is the result of the decreased heat release of inhibited reaction processes and the suppression of radical overshoot with the further decrease of the reaction rate due to the temperature decrease and mixture dilution. A comparison of the results of modelling laminar premixed methane/air flames inhibited by potassium bicarbonate (gas phase model, detailed kinetic model) with the results obtained using the suggested simple model is presented. The calculations with the detailed kinetic model demonstrate the following modes of combustion process: (1) flame propagation with chain-branching reaction (with radical overshoot, inhibitor addition decreases the radical overshoot down to the equilibrium level); (2) saturation of chemical influence of inhibitor, and (3) transition to thermal mode of flame propagation (non-branching chain mode of reaction). The suggested simple kinetic model qualitatively reproduces the modes of flame propagation with the addition of the inhibitor observed using detailed kinetic models. [ABSTRACT FROM PUBLISHER]

Published

2017

5. One-dimensional modelling of flame propagation in solid composite fuel with different geometrical configurations.

Author

Fursenko, Roman V., Gubernov, Vladimir V., Minaev, Sergei S., and Kurdyumov, Vadim N.

Subjects

COMPOSITE materials, FLAME, HEAT flux, THERMAL conductivity, ONE-dimensional flow, SINGLE step chemical reactions

Abstract

In this paper the propagation of combustion waves in solid composite energetic material consisting of fuel and highly thermal conductive inert elements is investigated using a one-dimensional model with a single step reaction mechanism. The analysis is focused on the study of the effect of the geometrical configuration of the composite material on flame speed and dynamics. Spatial averaging over directions transverse to the propagation direction is performed in such a way as to retain the multidimensional nature of the problem. It is shown that the regimes of combustion depend on the geometry of the composite. The largest possible flame speed enhancement is attained in cases when the heat fluxes along the structural elements are not disrupted. For each configuration selected, there exists an optimal choice of the geometric parameters that maximizes the flame velocity. [ABSTRACT FROM AUTHOR]

Published

2017